Example Irrigated Farm Water Use Efficiency Assessment...
Transcript of Example Irrigated Farm Water Use Efficiency Assessment...
Example Irrigated Farm Water Use
Efficiency Assessment (IFWUEA)
May 2016
This document supports the development of Irrigation Farm Water Use Efficiency Assessments
(IFWUEAs) as part of the NSW Sustaining the Basin: Irrigated Farm Modernisation program
(STBIFM) and contributes to the planning of on-farm infrastructure modernisation projects.
This document provides an example of what could be included in an IFWUEA and is indicative of
the standard of report that meets the expectations and criteria of the NSW Department of Primary
Industries (DPI). It should be noted that not all sections of this report will be applicable to every
enterprise. Those preparing an IFWUEA should use their own discretion as to which methodology
to use and which sections are applicable to their enterprise. The three main methodologies used
in describing farm water losses are:
Direct measurement of a particular component of the farm,
Detailed modelling of the whole farm to identify performance of the main components of the
irrigation system, and
Reporting of water supplied to the farm, cropped areas and yields with supporting evidence
for an extended period. Irrigation water losses can then be implied through comparison with
industry benchmarks.
The IFWUEA Form provides a template to assist in the preparation of an IFWUEA.
Table of Contents
Part 1 – Applicant Details
Part 2 – Property Description
Part 3 – Assessment of on-farm losses
Whole farm water balance
Assessments of Component Losses – surface irrigation systems
Assessment of Component Losses – pressurised irrigation systems
Statement of Losses
Appendices
Appendix 1: Farm locality map
Appendix 2: Irrigation area and layout
Appendix 3: EM survey
Appendix 4: Whole farm water balance
Appendix 5: Resources for the preparation of an IFWUEA
Appendix 6: Example Evidence of consultant’s certification
Appendix 7: Example Invoice to proponent
Appendix 8: Example Receipt to proponent
Appendix 9: Example Invoice to DPI
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Part 1: Applicant Details
Business name: Mr John Irrigator
Legal entity name: Top Farm Enterprises
Contact Person: John
ABN: XX XXX XXX XXX
Postal Address:
‘Top Farm’, Waterville, NSW
PO Box 11
Waterville NSW 2222
Phone: XX XXXX XXXX
Mobile: XX XXXX XXXX
Email: [email protected]
Part 2: Property details
Refer to STBIFM Guidelines for information on the area covered by an IFWUEA www.dpi.nsw.gov.au/info/sustainingthebasin
Property name: “Top Farm”
Contact person: Bob Manager
Property address and postal address
‘Top Farm’, Waterville, NSW
Phone: XX XXXX XXXX Mobile: XX XXXX XXXX
Lot and DP(s) Lot X, DP XXXXXXX, Parish of Waterville, County of outback
Area of property (ha)
5000 Area irrigated (ha): 2200
Total area of irrigation development proposed
2200 Remainder (if any) of total area: (ha)
2800
You may wish to attach additional information to provide a brief description of the on-farm situation.
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Water Resources
Water Access Licence Information
WAL number WAL number WAL number
WAL XXXXX 5,500 ML
WAL XXXXX 10,000 ML
WAL XXXXX 4,500 ML
Attach additional sheets if required.
Summary of Water licences held (Shares):
General security entitlement: 10,000 ML
Supplementary entitlement: 10,000 ML
Groundwater entitlement: 2,250 ML
Harvestable Right 250 ML
Unregulated Right Nil
Floodplain Harvesting To Be Determined
Total water resource: 22,500 ML
If you have a verified IFWUEA that describes the Irrigation Management Area for which you may wish to submit an infrastructure funding application there is no requirement to complete another IFWUEA. Please conclude this form here and return it to DPI.
However, if you wish to modify your existing IFWUEA to include additional areas or water losses please complete the following pages.
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Description of current irrigation systems, crops and their management The farm maps in Appendices 1, 2 and 3 include field details, current irrigation infrastructure, individual
farm management areas and EM survey results.
Water is supplied by gravity from the east via a joint water supply authority.
Irrigation is mainly carried out using a surface application system on 2080 ha, which consists of poly
siphons discharging into rota bucks and furrows. Rota bucks / siphon / furrow combinations are changed
throughout the season. 120 ha are used for intensive Lucerne production using a pressurised irrigation
system.
All irrigation drainage water can be recirculated. An above ground irrigation storage is used to capture
recirculated water or water supplied from the river via a pumping station located at the storage. Some
command for gravity irrigation over all fields can be achieved when the water level in the storage is more
than half full.
The first stage of irrigation development occurred in the early 1980s with final works completed in 1987.
During the last decade Mr Irrigator has made minor improvements to increase on-farm water use
efficiency and reduce water losses. A number of fields and channels in the water management areas
have been realigned to improve water application efficiency.
The surface irrigation cropping program is a cotton system with the majority of available water used for
that purpose. Up to 850ML has been used for irrigation of Lucerne and the rest of the crop and pasture
rotations are rain fed. It is a goal to use winter cereal grain, grazing and hay to fatten vealers.
The lucerne is irrigated by a hand-shift spray line system consisting of 50 lengths of 9m pipe each with
double nozzle Naan sprinklers with nominal sizes of 3.2 mm x 2.0 mm at one end. This system irrigates
30 ha of Lucerne with 42 shifts taking 21 days. The spray lines are supplied by underground mainlines
and hydrants.
‘Top Farm’ currently utilises capacitance probes to schedule irrigations. Automatic logging and
transmission of data to home and office computers allows soil moisture to be monitored in real time. A
refill point is determined by analysing the soil drying cycle.
Part 3: Assessment of on-farm losses
Whole farm water balance (surface system)
Note: The water balance is used for the assessment of the surface irrigation system and the pressurised
system is examined separately.
Whole farm water balance assessments were conducted over two contrasting seasons to determine
whole farm water losses and efficiencies. Total water supplied for these seasons is shown in Table 1.
Regulated water delivery information was retrieved from iWAS (State Water) (Appendix 4). Estimates
were made of supply from rainfall runoff and other sources and it is noted that these total less than 15%
of the aggregate.
Cotton plantings in the 2011-12 and 2012-13 seasons were 1,595 ha and 750 ha respectively.
The 2011-12 season had a good start in terms of in-crop rainfall but had a dry finish, whereas the 2012-
13 season had a dry start and wet finish.
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Industry comparison of Farm Water Use Efficiency
Irrigation Water Use Efficiency Index (IWUIfarm) relates total production to the amount of irrigation water
supplied. The average IWUIfarm for 46 cotton farms surveyed by DPI in 2008-09 was 1.97 bales/ML, with
values ranging between 0.82 and 5.72 bales/ML (refer to Appendix 8).
Another index for comparing irrigation water use between farms in differing regions and across seasons is
the Gross Production Water Use Index (GPWUI farm). It relates total production to the total amount of
water used from all sources (i.e. irrigation water, effective rainfall and soil moisture). From surveys of
cotton farms, DPI found the industry average GPWUI farm for the 2006-07 season was 1.13 bales/ML and
in the 2008-09 season 1.14 bales/ML, with values ranging between 0.64 and 1.58 bales/ML.
The GPWUI calculated for the 2011-12 and 2012-13 seasons at ‘Top Farm’ of 0.93 and 0.99 respectively
suggest significant improvements in water use efficiency are possible. A GPWUI of around 0.93-0.99 is
less than the average observed in the both the DPI 2006-07 and 2008-09 benchmarking studies.
According to the results of the benchmarking study the top 20% of cotton irrigators are achieving GPWUI
greater than 1.25 bales /ML. A detailed assessment of on-farm water losses is outlined in the following
sections of this report. The following farm water balance analysis was undertaken to calculate seasonal
water losses at ‘Top Farm’ (Table 1).
Table 1: Comparative whole farm water balance (surface system)
Whole farm water balance period NSW DPI 2008-09
Cotton
Benchmarking
2011-2012 2012-2013
Cotton production area 1595 750
Yield (bales/ha) 9.1 10.0
Total seasonal water use (ML/ha) 9.75 10.13
Theoretical crop water use (ML/ha) 8.30 8.80
Crop water use index (bales/ML) AVE 1.41 1.10 1.14
Irrigation Water Use Index – IWUI (bales/ML) AVE 1.97 1.26 1.58
Gross Production Water Use Index – GPWUI
(bales/ML)
AVE 1.14 0.93 0.99
Estimated total farm water losses (ML) 2313 1000
Estimated whole farm efficiency (%) 80 79
A detailed whole farm water balance for the 2012-13 seasons is documented in Appendix 5.
Irrigation performance indicators would improve significantly if yields were to increase to 12 bales/ha, a
yield which is commonly viewed as an industry benchmark.
Possible areas to investigate would be current agronomic and irrigation scheduling practices. It is also
recommended that current agronomic practices be reviewed by a professional agronomist to ascertain if
there are any agronomic constraints to crop performance.
Despite this, a whole-farm efficiency of 80% for surface irrigated cotton is not a poor result. Previous
research studies and whole-farm water use efficiency audits have found whole farm efficiency is often
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below 70% (see Appendix 6). It is reasonable to expect that performance above 80% is achievable with
well planned investment.
Assessment of Component Losses – surface irrigation systems
In order to determine farm water loss, various physical and theoretical studies were conducted. Field
numbering is identified in Appendix 2.
Distribution System Assessments
In 2010-11 seepage rates in Storage 1 were measured at 2 mm/day. In addition some channel lockup
tests were done on F1 and F8 which produced similar results. It is known that the soils on ‘Top Farm’ are
fairly uniform (grey cracking clays) as this has been verified on a large proportion of the farm by an EM
survey (Appendix 3) conducted in 2000. Based on this work, seepage losses from all on-farm irrigation
infrastructure were assumed to be 2 mm/day.
Estimations of the seepage losses associated with the various parts of the farm are shown in Table 2.
Table 2: Estimated surface irrigation loss summary for ‘Top Farm’.
11-12 Season 12-13 Season
Storage Losses 1388 ML 610 ML
Channel Losses 139 ML 40 ML
Drain Losses 208 ML 60 ML
Field Losses 578 ML 290 ML
Total Losses 2313 ML 1000 ML
Storage Performance
As can be seen from both of the seasons evaluated (Table 2) the largest losses occurred in the storages.
Generally, on this farm, water is collected in the late summer and early autumn months, with most of it
being used in the following summer season. Therefore, this water is stored for 5-8 months prior to being
used. Based on this, the need for efficient water storage is paramount.
‘Top Farm’ has three storages consisting of one large rectangular ring tank, and two small below ground
storages (tail water surge areas). This report will focus on potential mitigation options for the large
rectangular ring tank (Storage 1).
The dimensions for Storage 1 were obtained from design plans and an on-site inspection.
Application system assessments
As a result of discussions with ‘Top Farm’ management it was agreed that the irrigation application
efficiency of F2 be investigated. This decision was driven by suspicions by ‘Top Farm’ management that
significant water losses were occurring through deep drainage, a product of excessive runtimes, a long
field length of 885m and relatively low siphon flow rates and head ditch capacity.
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A series of evaluations were undertaken to determine irrigation efficiencies, and to establish if
management changes or field redesign could save water. In F2, initial evaluations suggest that
efficiencies could be optimised by halving the field length, increasing siphon flow rates and reducing the
run time (Table 3).
Table 3: Surface Irrigation Performance Evaluation Results for F2
Pre-management
change/field redesign
Post management
change/field redesign
Measurements Measured Event Optimised Event
Field Length (m) 885 408
Flow Rate (L/s) 2.70 3.8
Time Water Applied (hours) 20 6
Deficit (mm) 60 60
Inflow (mm) 110 83
Tail water (mm) 27 21
Water Infiltrated (mm) 83 62
Application Efficiency (85% of tail water recycled) 69% 92%
Distribution Uniformity (DU) 68% 92%
Potential Water Saving (ML/Ha) 0.22
Assessment of Component Losses – pressurised irrigation
systems
Distribution System Assessments
In order to determine farm water loss, various analyses were conducted.
Distribution losses
Some delivery pipes have small leaks that were quantified by direct measurement.
Field losses
The hand shift spray line joints also leak and direct measurement of a percentage of these joints provided
an estimate of the total field pipe losses.
Distribution Uniformity (DU) was assessed by completing a catch can test using NSW DPI Prowater®
methodology.
(Evaluating a pressurised irrigation system according to the ProWater® methodology – in Appendix 6 of
this document and available at: http://bit.ly/IrrigationEvaluation).
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Whole Farm Benchmark Performance
Production losses
Table 4 is a sumary of water usage on the spray irrigation fields for the purpose of production loss
assessment.
Table 4: Summary of water usage on the spray irrigation fields
Year Allocation plus purchase ML Usage ML
2003 388 388
2004 652 652
2005 850 850
2006 253 253
2007 255 255
2008 648 648
2009 560 560
2010 612 0
2011 850 850
2012 343 343
Average 517.3 394.9
An observed problem with the current pressurised system is the inability to get around the lucerne fields
quickly enough to put on moderate amounts of water. It tends to take more than a fortnight to return to the
starting point which leads to the typical scenario of application of 80 to 160 mm water every 10 to 20
days.
It is noted that best practice for lucerne production is to apply the crop water requirement on 10 to 14 day
intervals and that substantially higher water use efficiency has been observed from this practice on other
sites. A change from monthly to fortnightly irrigation intervals is said to increase yield by 30 to 50%
without using any additional water, based on various studies. (See references in Appendix 6).
By calculating the whole farm gross production water use index (GPWUI) it is evident that performance of
the lucerne production system is well below the industry benchmark.
Because all of the significant loss for the most recent years occurs in the cropped area, the extent of loss
can be modelled based on the improved scenario of crop production. A target production level of 10
10
tonnes/ha of lucerne was used, based on an expected improvement of dry matter yield from 8 of 20% by
closing the watering interval to once a fortnight (Appendix 7).
It is assumed that a linear relationship exists for the production function of lucerne yield and water use,
within the range being examined in this report.
Scheduling assessment
The production losses that occur in the field can be estimated by looking at what area would be required
to achieve the same production of tonnes of lucerne hay if the losses were fixed. It is reasonable to think
that improved irrigation scheduling could achieve at least a 20% increase in yield per hectare. This would
occur through reduced production losses due to waterlogging and reduced deep drainage losses due to
over watering at the beginning of each irrigation, and reduced production losses due to under watering at
the end of each irrigation. If overall farm production was kept the same, only 83% of the 120 ha Lucerne
area is required for the same production. The water which was being applied to the extra 17% of area
could be considered to be the loss in this scenario. Using this methodology water loss is calculated as
the average irrigated water use per hectare (5.1 ML/ha) by the 20 hectares no longer required to be
irrigated to produce the same yield, giving 102 ML of loss per annum.
Application system assessments
Some water is inevitably lost from a spray irrigation system. Some of this is from evaporation and droplet
drift off the irrigated field. A reasonable assumption is that this would be around 10%for a system that is
performing well1.
Distribution Uniformity (DU) losses are calculated by the difference between the measured DU (68%) and
an industry standard of 85%. This is then multiplied across the maximum normal water use of the
properties irrigation system. The water use of 850 ML occurred in 2005 and 2011 (Table 4), so the losses
due to poor DU are 85%– 68% = 17%, and 17% of 850 ML = 144 ML. Estimated losses for the various
pressurised irrigation system components are shown in Table 5.
Table 5: Estimated loss summary for pressurised system
2011-12 Season 2012-13 Season
Mainline Losses 5 ML 3 ML
Spray line Losses 85 ML 34 ML
Field Losses (DU) 144 ML 58 ML
Production losses 102 ML 41 ML
Total Losses 336 ML 136 ML
1 J. Uddin, N.H. Hancock, R.J. Smith, J.P. Foley (2013) Measurement of evapotranspiration during sprinkler irrigation using a
precision energy budget (Bowen ratio, eddy covariance) methodology, Agricultural Water Management, 116:89-100.
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Statement of Losses
Discussion
Total on-farm water losses for the 2011-12 and 2012-13 cotton seasons were estimated at 2,649 and
1,136 ML respectively. Whole farm water use efficiency was estimated to be around 70% for both
seasons. The results confirmed that for the 2011-12 and 2012-13 cotton seasons:
Water storage losses contributed 53-55% of total losses
Field losses contributed 28-31% of total losses, 75 to 80% of those losses from the surface fields
Channel and drain losses contributed 10% of total losses
All other components were less than 10%.
The whole farm water balance assessments on cotton seasons 2011-12 and 2012-13 suggest whole farm
efficiency is comparatively good at 70%. However, infrastructure investment has the potential to deliver
further water savings and boost whole farm water use efficiency. The largest losses occurring on “Top
Farm” were from the storages and this should be a priority area for improvement. The infrastructure
improvements should focus on potential mitigation options from surge area to the large rectangular ring
tank.
Field losses were also high. Combine these with low GPWUI and there is potential to improve both by
increasing flow rates. This will reduce field seepage losses and reduce water logging and potentially
increase the GPWUI. Other possible areas to investigate are the current agronomic and irrigation
scheduling practices.
The spray system’s total losses are small compared to the surface system losses due to its relatively
small area. Within that area, field and production losses need to be addressed to bring the irrigation
system up to an industry standard performance.
In summary, it is estimated that up to 2649 ML could be lost from useful crop production (Table 6).
Table 6: Combined (pressurised and surface) summary of losses from Tables 2 and 5
2011-12 Season 2012-13 Season
Storage losses 1388 ML 610 ML
Channel losses 139 ML 40 ML
Drain losses 208 ML 60 ML
Mainline losses 5 ML 3 ML
Spray line losses 85 ML 34 ML
Field losses (DU) surface 578 ML 290 ML
Field losses (DU) spray 144 ML 58 ML
Production losses 102 ML 41 ML
Total losses 2649 ML 1136 ML
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IFWUEA Verification Checklist
This checklist is to be used to ensure all appropriate documentation is provided to DPI to assess your IFWUEA. Please complete and provide with your IFWUEA document.
Please list IFWUEA water losses Office Use
Supporting Evidence
Office Use
(DPI Assessment)
Losses 1 Storage 1388 ML
Losses 2 Distribution 437 ML
Losses 3 Field 722 ML
Losses 4 Production 102 ML
Total 2649 ML
Evidence attached
(Tick to confirm)
Office Use
(DPI Assessment)
Farm map
Evidence of consultant certification
Consultant Invoice attached
Consultant receipt attached
Invoice made out to DPI to 80% of the total cost to a maximum of $2000 ex GST
Consultant declaration: I, Mr Consultant (name) declare that the losses presented in the IFWUEA are a true and accurate estimation based on reasonable assessment methodologies and assumptions.
Signature: XXX Date: xx/xx/xxxx
Irrigator declaration: I, John Irrigator (name) declare that I am satisfied that the losses identified in the IFWUEA are a reliable estimation of on-farm water losses.
Signature: XXX Date: xx/xx/xxxx
Offic
e U
se
Only
Previous funding for water use assessment services Yes No
IFWUEA verified by Yes No
DPI Initials: Date: TRIM Ref:
E:
13
Appendix 1: Farm locality map
Appendix 2: Irrigation layout
9/755117
7006/1060943
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Appendix 2: Irrigation area and layout
Supply channels are shown in blue. Water is supplied by a scheme channel to the east.
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Appendix 3: EM survey
Appendix 4: Seasonal whole farm water balance (Whole Farm Water Balance Work Sheet – September 2012 to June 2013)
Production details Soil Water
(A) Area grown ha (cotton) 750 (R) Used Soil reserve (mm) average of all fields 180
(B) Total Production (Bales) 7520 (S) Used Soil reserve ML = (R ÷ 100) x A 1350
(C) Average Yield (Bales/ha) = B ÷ A 10.0 (T) Total seasonal water usage (ML) = L + Q + S 7600
Water supply Water use summary
(D) Total water pumped (bore) NA ML/ha pumped = F ÷ A 4.81
(E) Total water pumped (river) 3605 ML/ha effective rainfall = Q ÷ A 2.00
(F) Total water pumped (ML) = D + E 3605 ML/ha irrigation water applied = L ÷ A 6.33
(G) On farm storage at planting (ML) 295 ML/ha used soil reserve = S ÷ A 1.80
(H) On farm storage at harvesting (ML) 50 ML/ha total water usage= T ÷ A 10.13
(I) Used from farm storage (ML) = G – H 245 (U) Total seasonal crop water use (ETc) mm 880
(J) On farm harvested including rainfall on storage (ML) 1150 Water Use Indices
(K) Water used on other crops (ML) 250 Crop Water Use Index (kg/mm/ha) = (C x 226) ÷ U 2.57
(L) Total irrigation applied on cotton (ML) = F + I + J – K 4750 Crop Water Use Index (Bales/ML) = C ÷ (U ÷ 100) 1.14
Rainfall Gross Production WUI - Farm (Bales/ML) = B ÷ T 0.99
(M) In season rainfall (mm) 280 Irrigation WUI - Farm (Bales/ML) = B ÷ L 1.58
(N) Run-off (green ha) (mm) 80 Farm Irrigation Efficiency
(O) Effective rainfall estimate (mm) = M – N 200 (V) Irrigation water used for ET (mm) = U – O – R 500
(P) Rainfall efficiency (%) = (O ÷ M) x 100 71 (W) Irrigation water used for ET (ML) = V x (A ÷ 100) 3750
(Q) Estimated effective rainfall for farm (ML) = (O ÷ 100) x A 1500 (Y) Estimated total farm water losses (ML) = L – W 1000
Whole farm irrigation efficiency (%) = (W ÷ L) x 100 79
Appendix 5: Resources for Preparation of an IFWUEA
The following are examples of relevant and valuable resources which may be used for the preparation of the
IFWUEA. This is not a comprehensive list of tools to prepare an IFWUEA, nor is there any requirement for these
tools to be used. Other similar, or better, tools may exist. Listing of a tool here is not in any way an endorsement
of the tool and users should be aware the tool may have changed since it was considered by DPI. Use of tools
below is entirely at the risk of the user.
Resource: 2008-09 Cotton Benchmarking Survey
NSW DPI 2008-09 Cotton Benchmarking Survey from http://www.australiancottonconference.com.au/LiteratureRetrieve.aspx?ID=76551
Resource: Evaporation data and storage trends
Monthly Evaporation at ‘Top Farm’ (source: ‘Ready Reckoner’ – Monthly Evaporation Calculator bureau of meteorology 2014)
Av. 1.14 bales/MLAv. 1.97 bales/MLAv. 1.41 bales/ML0
1
2
3
4
5
6
Crop Water Use Index
(CWUI) (bales/ML)
Irrigation Water Use Index
(IWUI) (bales/ML)
Gross Production Water Use
Index
(GPWUI) (bales/ML)
ba
les
/ M
L
Monthly Evaporation
0
50
100
150
200
250
300
350
Janu
ary
Febru
ary
Mar
chApr
il
May
June
July
Aug
ust
Sep
tem
ber
Octobe
r
Nove
mbe
r
Dece
mbe
r
Dep
th o
f E
vap
ora
tio
n (
mm
)
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The typical water storage pattern for ‘Top Farm’ Storage 1 can be seen in the figure below.
Monthly Water Storage Pattern for RES 1 at ‘Top Farm’
Resource:
Water Access Licence Conditions Register
http://registers.water.nsw.gov.au/wma/AccessLicenceNoSearch.jsp?selectedRegister=AccessLicense
Resource: Calculating Mean Application Rate (MAR) and Distribution Uniformity (DU)
Introduction to irrigation management – Evaluating your pressurised system
http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0009/176643/irrigation-evaluation-1.pdf
Introduction to irrigation management – Lateral boom and linear move
http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0008/176651/irrigation-evaluation-2.pdf
Introduction to irrigation management – Centre pivots
http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0009/176652/irrigation-evaluation-3.pdf
Introduction to irrigation management – Spray lines Side roll; end tow; hand shift
http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0010/176653/irrigation-evaluation-4.pdf
Introduction to irrigation management – Fixed under-canopy micro systems and fixed overhead, solid set and
bike shift
http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0009/176661/irrigation-evaluation-5-6.pdf
Introduction to irrigation management – Non-overlapping under-canopy spray system
http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0010/176662/irrigation-evaluation-7.pdf
Introduction to irrigation management – Drip (trickle) systems
http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0019/164431/evaluating-pressurised-system.pdf
Storage Volume Pattern
0
10
20
30
40
50
60
70
80
90
Janu
ary
Febru
ary
Mar
chApr
il
May
June
July
Aug
ust
Sep
tem
ber
Octobe
r
Nove
mbe
r
Dece
mbe
r
Sto
arg
e V
olu
me %
19
Example summary of steps used to calculate Mean Application Rate (MAR)
MAR = average application depth ÷ test time (minutes) x 60
Total volume in all catch cans 2116 ml A
Catch-can diameter 113 mm B
Conversion factor for catch-cans 10.0 C
Convert catch can volume into depth (mm) = volume ÷ conversion factor
Total depth of application = A ÷ C
= 2116 ÷ 10.0
= 211.6 mm
D
Number of catch cans between spray line positions 36 E
Average depth of application = D ÷ E
= 211.6 ÷ 36
= 5.88 mm
F
Test duration 30 minutes G
MAR = F ÷ G x 60
Convert rate of application into hours
= 5.88 ÷ 30 x 60
= 11.8 mm per hour
MAR
In a well-designed system, the MAR figure for the whole irrigation should be less than or equal
to the infiltration rate of the soil.
Infiltration rate of soil 15 mm per hr H
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Calculating Distribution Uniformity (DU) —side roll, end tow, hand shift
This calculation uses the catch totals to take into account overlap from adjacent spray line positions rather than
individual catch-can amounts. The table below summarises the steps used to calculate DU.
Summary of steps used to calculate DU
LQ cans = number of catch cans between lateral positions ÷ 4
(If not a whole number round down)
= E ÷ 4
= 36 ÷ 4
= 9
LQ
cans
On your overlap addition table, highlight the lowest totals for the appropriate number of Lowest Quarter (LQ)
cans. These are your lowest quarter catch cans (LQ cans) (see above, i.e. the lowest 9 catch-can totals)
Total volume of the selected LQ cans = 48 + 47 + 46 + 37 + 45 + 37 + 47 + 37 + 31
= 375 mL
K
Convert Total LQ volume into depth = LQ volume (mL) ÷ conversion factor
= K ÷ C
= 375 ÷ 10.0
= 37.5 mm
L
LQ average depth of application = total depths of LQ cans ÷ number of LQ cans
LQ Average depth = L ÷ LQ cans
= 37.5 mm ÷ 9 cans
= 4.17 mm
N
Average LQ application rate = LQ average depth ÷ test time (minutes) x 60
= N ÷ G x 60
= 4.17 ÷ 30 x 60
= 8.34
P
DU = average LQ application rate ÷ MAR
= P ÷ MAR
= 8.34 ÷ 11.76
= 0.709 mm
DU
Convert DU into a percentage = DU x 100
= 0.709 x 100
= 70.9% Round up to 71%
A DU of 85% is acceptable for spray lines. If the DU is below this, then changes to your irrigation system may
be required in order to improve the DU%. It is a good idea to check the original specifications supplied with the
irrigator to make sure the system is operating correctly.
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Appendix 6: Example Evidence of consultant’s certification
22
Appendix 7: Example Invoice to proponent
23
Appendix 8: Example receipt to proponent
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Appendix 9: Example Invoice to DPI
1 Name
Address
Phone 2 ABN XX XXX XXX XXX 3
Date: 00/00/0000 4 TAX INVOICE No. XXXX5
To:6
NSW Department of Industry
Attn: STBIFM Program
Wagga Wagga Agricultural Institute
Private Mail Bag
WAGGA WAGGA NSW 2650
ABN 72 189 919 072
DESCRIPTION QTY
UNIT
PRICE (excl
GST)
SUB
TOTAL
(excl GST)
GST
AMOUNT
AMOUNT
PAYABLE
(incl GST)
Project No: EXXX
IFWUEA Reimbursement7
71 2,000.00 2,000.00
800.00 2,000.00
Totals 2,000.00 00.00 2,000.00
TOTAL (excl GST) 92,000.00
TOTAL GST AMOUNT PAYABLE 9
0.00
TOTAL AMOUNT PAYABLE (incl GST) 9
2,000.00
25
Please refer to numbered references on the sample invoice
1 The identity of the supplier (business trading name, address and telephone number at the top. 2 The ABN of the supplier at the top. 3 The date of issue of the tax invoice at the top, on the right hand side. 4 That the document is intended as a tax invoice, such as including the words ‘tax invoice’ at the top. 5 An ‘invoice number’ shown prominently alongside the words ‘tax invoice’. 6 Department of Industry’s details, ABN and contact person’s details. 7 A unit description of each good or service supplied, including quantities. 8 An indication of which goods don’t include GST by showing a ‘zero’ in the GST payable column 9 The GST exclusive price, the GST amount and the GST inclusive price for each item, together with the
totals for these, vertically in the bottom right hand corner.
© State of New South Wales through Department of Industry, Skills and Regional Development 2016. You may copy, distribute and otherwise freely deal
with this publication for any purpose, provided that you attribute the Department of Industry, Skills and Regional Development as the owner.
Disclaimer: The information contained in this publication is based on knowledge and understanding at the time of writing (May 2016). However,
because of advances in knowledge, users are reminded of the need to ensure that information upon which they rely is up to date and to check currency of the information with the appropriate officer of the Department of Primary Industries or the user’s independent adviser.
Published by the Department of Primary Industries, a part of the Department of Industry, Skills and Regional Development.
INT16/39670